System and method for parsing multiple sets of data

ABSTRACT

Software, resident or a host computer, that is capable of parsing a data stream of multiple interleaved data signals into the individual data signals that are then ready for manipulation and further processing by the host computer.

FIELD OF THE INVENTION

The present invention relates generally to the field of optical scanners and more particularly to a system and method for parsing dual sets of scan data. In particular, this invention provides a system and method for parsing dual image scan data obtained from either a dual image scan with two scan data images interleaved or from two separate scans with the two scan's data interleaved when it is sent to the host computer.

BACKGROUND OF THE INVENTION

Optical scanners are used to capture and digitize images. For example, an optical scanner can be used to capture the image of printed matter on a sheet of paper. The digitized image can then be electronically stored and/or processed with character recognition software to produce ASCII text. Most optical scanners use illumination and optical systems to illuminate the object and focus a small area of the illuminated object, usually referred to as a "scan line," onto the optical photosensor array. The entire object is then scanned by sweeping the illuminated scan line across the entire object, either by moving the object with respect to the illumination and optical assemblies or by moving the illumination and optical assemblies relative to the object.

A typical scanner optical system will include a lens assembly to focus the image of the illuminated scan line onto the surface of the optical photosensor array. Depending on the particular design, the scanner optical system may also include a plurality of mirrors to "fold" the path of the light beam, thus allowing the optical system to be conveniently mounted within a relatively small enclosure.

While various types of photosensor devices may be used in optical scanners, a commonly used sensor is the charge coupled device or CCD. As is well-known, a CCD may comprise a large number of individual cells or "pixels," each of which collects or builds-up an electrical charge in response to exposure to light. Since the size of the accumulated electrical charge in any given cell or pixel is related to the intensity and duration of the light exposure, a CCD may be used to detect light and dark spots on an image focused thereon. In a typical scanner application, the charge built up in each of the CCD cells or pixels is measured and then discharged at regular intervals known as exposure times or sampling intervals, which may be about 5 milliseconds or so for a typical scanner. Since the charges (i.e., image data) are simultaneously collected in the CCD cells during the exposure time, the CCD also includes an analog shift register to convert the simultaneous or parallel data from the CCD cells into a sequential or serial data stream.

A typical analog shift register comprises a plurality of "charge transfer buckets" each of which is connected to an individual cell. At the end of the exposure time, the charges collected by each of the CCD cells are simultaneously transferred to the charge transfer buckets, thus preparing the CCD cells for the next exposure sequence. The charge in each bucket is then transferred from bucket to bucket out of the shift register in a sequential or "bucket brigade" fashion during the time the CCD cells are being exposed to the next scan line. The sequentially arranged charges from the CCD cells may then be converted, one-by-one, into a digital signal by a suitable analog-to-digital converter.

In most optical scanner applications, each of the individual pixels in the CCD are arranged end-to-end, thus forming a linear array. Each pixel in the CCD array thus corresponds to a related pixel portion of the illuminated scan line. The individual pixels in the linear photosensor array are generally aligned in the "cross" direction, i.e., perpendicular to the direction of movement of the illuminated scan line across the object (also known as the "scan direction"). Each pixel of the linear photosensor array thus has a length measured in the cross direction and a width measured in the scan direction. In most CCD arrays the length and width of the pixels are equal, typically being about 8 microns or so in each dimension.

The sampling rate in the cross direction is a function of the number of individual cells in the CCD. For example, a commonly used CCD photosensor array contains a sufficient number of individual cells or pixels to allow a sampling rate in the cross direction of about 600 pixels, or dots, per inch (600 ppi), which is referred to herein as the native sampling rate in the cross direction.

The sampling rate in the scan direction is inversely related to the product of the scan line sweep rate and the CCD exposure time (i.e., the sampling interval). Therefore, the sampling rate in the scan direction may be increased by decreasing the scan line sweep rate, the CCD exposure time, or both. Conversely, the sampling rate in the scan direction may be decreased by increasing the scan line sweep rate, the CCD exposure time, or both. The "minimum sampling rate in the scan direction" for a given exposure time is that sampling rate achieved when scanning at the maximum scan line sweep rate at that exposure time. For example, a maximum scan line sweep rate of about 3.33 inches per second and a maximum exposure time of about 5 milliseconds will result in a minimum sampling rate in the scan direction of about 60 ppi.

Currently, optical character recognition (OCR) requires 300 ppi sampling rates for accurate results. Thus, a 300 ppi 4 bit gray scan (8.5×11), which is high resolution, low bit depth, is approximately 4.2 Megabytes. Color fidelity requires a 24 bit color scan. Thus, a 150 ppi 24 bit color scan (8.5×11), which is low resolution, high bit depth, is approximately 6.3 Megabytes. In order to provide a scan of a document that has both color pictures or drawings and writing requiring OCR, the scan would have to be approximately 300 ppi at 24 bits (8.5×11) which corresponds to 25.24 Megabytes of memory. Accordingly, to scan a document that includes both text and pictures would require quite a bit of memory. Yet, the software on the computer will down sample the color image to approximately 6.3 Megabytes and throw away the color image to obtain the text. This process is extremely slow to perform in software and unnecessarily consumes a great deal of memory. Another alternative is to first scan either the text or the graphics and then perform a scan of the other. Then the document could be regenerated by software. However, this is also a very time consuming method of scanning the document, besides using a lot of memory as well.

Accordingly, it would be desirable to provide a scanner that is able to scan a document containing both text and graphics, and greatly reduce the total amount of data being sent from the scanner to the host computer (which is currently a speed constraint), and reduce the total amount of data being stored and processed by the host computer software.

SUMMARY OF THE INVENTION

The above and other aspects of the present invention are accomplished in a software program that is capable of parsing multiple data signals that are sent to the host computer in a single interleaved stream of data. It should be noted that although the description herein entails parsing an interleaved stream of dual image signals sent from a scanner, this should not being limiting to the concept of parsing dual image signals, but rather extends to parsing multiple interleaved data signals from any source.

One implementation of the present invention may include a multiple image scanner that performs a single scan of a document containing multiple types of images (e.g., text and graphics) and send multiple renditions of the same document from the scanner to the host computer (e.g., one high resolution gray scale image, and one low resolution high bit depth color image), thus greatly reducing the total amount of data sent to and processed by the host computer, for example, from approximately 25.24 Megabytes to approximately 10.5 Megabytes (a 300 ppi 4 bit gray image 8.5×11! that is 4.2 Megabytes and a 150 ppi 24 bit color 8.5×11! that is 6.3 Megabytes), which is a 2.4 to 1 reduction.

The scanner of the present invention may send the muliple images to the host computer interleaved on a line basis, for example, with two lines of high resolution gray data and then one line of low resolution color data, if the resolution ratio between the images was two. The advantage of the present invention is less information for the host software to process and store, and less information to be sent from the scanner to the host, which is a current limitation on scanner speed.

The present invention would further comprise host computer software that is capable of parsing the data stream of interleaved images into the individual images that are then ready for manipulation and further processing by the host computer.

The present invention may comprise a method for parsing an interleaved multiple data stream into the individual data streams contained in the interleaved multiple data stream, said method comprising the following steps: (a) determining the data type and other parameters of each of the individual data streams contained in the interleaved multiple data stream; (b) calculating the data ratios for each individual data stream contained in the interleaved multiple data stream; (c) receiving the interleaved multiple data stream; (d) copying each line of the individual data streams into predetermined buffers; (e) switching between the individual data streams based on the data ratios calculated in step (b) above; and (f) returing to step (c) until the interleaved multiple data stream is completed.

The present invention may more particularly provide a method for parsing an interleaved multiple image data stream into each individual view contained in the interleaved multiple image data stream, said method comprising the following steps: (a) determining the data type and other parameters of each individual view contained in the interleaved multiple image data stream; (b) calculating the image ratios for each individual view contained in the interleaved multiple image data stream; (c) receiving the interleaved multiple image data stream; (d) copying each line of the individual views contained in the interleaved multiple image data stream into predetermined buffers; (e) switching between the individual views contained in the interleaved multiple image data stream based on the image ratios for each view calculated in step (b) above; and (f) returning to step (c) until the interleaved multiple image data stream is completed.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of the present invention will be better understood by reading the following more particular description of the invention, presented in conjunction with the following drawings, wherein:

FIG. 1 shows a block diagram of the data path for a multiple image scanner according to the present invention;

FIG. 2 shows a more detailed block diagram of the data path of the image pre-processor for a multiple image scanner according to the present invention;

FIG. 3 shows a more detailed block diagram of the data path of the image post-processor for a multiple image scanner according to the present invention;

FIG. 4 shows a more detailed block diagram of the data path from the multiple image scanner to the host computer according to the present invention; and

FIG. 5 shows a flow chart of a method of parsing a data stream containing more than one set of data according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention provides a scanner that is capable of obtaining two sets of scan data simultaneously from a single scan. While the region of the scan is the same, the data types and resolutions of the two views can vary. For example, when a scan of a document is performed, an image processing unit in the scanner will generate one high resolution gray scale image and one low resolution 24 bit color image of the document scanned and then send both renditions of the scanned document to a host computer interleaved in a data stream, which the host computer will then parse in order to recreate the two views of the scanned document.

FIG. 1 shows a block diagram of the data path for a dual image scanner with dashed line area 100 being scanner functions implemented by an image processeing unit and dashed line area 102 being host computer functions. It should be noted that although the embodiment being described herein is a dual image scanner comprising a black and white and a color image, the concepts are extensible to multiple images. Image processing unit 100 is implemented in an ASIC with functional details described below with respect to FIGS. 2 and 3. When a document is scanned, a CCD array 104 or other known photosensor device outputs a red data signal 106, a blue data signal 108 and a green data signal 110. These three data signals are then converted into a color image data signal 128 and a monochrome image data signal 130 by an image pre-processor 112. The image pre-processor 112 places the color image data signal 128 into a color buffer portion 118 of buffer 114 and the monochrome image data signal 130 into a monochrome buffer portion 116 of buffer 114.

Next the image post-processor 120 uses the image data in the color buffer 118 and the monochrome buffer 116 to generate either 1 or 2 views of the window scanned by the scanner as specified by the host computer. If two views are generated, the image post-processor will send the two views to the host computer in an interleaved data stream 136.

When the host computer receives the two views of the scan window, a data parser 122 will parse the data stream 136 into a color image 124 and a monochrome image 126. The two views are then ready to be manipulated by the host computer. The advantage is less information for the host software to process and store, and less information to be sent from the scanner to the host, which is a current limitation on the speed of scanners.

I. MULTIPLE IMAGE SCANNER

The dual image scanner reduces the data required to be sent from the scanner to the host computer for complete page (text and graphics/image) information with one scan. Currently optical character recognition requires 300 ppi sampling rates for accurate results. For color fidelity, a 24 bit color scan is required. In order to do this, the typical scan would be 300 ppi at 24 bits (8.5×11), which is 25.24 Megabytes. By letting the scanner send two renditions of the same page, one high resolution gray scale image, and one low resolution 24 bit color image, the total amount of data sent to and processed by the host software is greatly reduced. A 300 ppi 4 bit gray (8.5×11) is approximately 4.2 Megabytes and a 150 ppi 24 bit color (8.5×11) is approximately 6.3 Megabytes for a total of 10.5 Megabytes, which is approximately a 2.4 to 1 reduction in data.

The multiple image scanner of the present invention has an image processing unit which performs the above operations very fast. The image processing unit may be implemented in a conventional field programmable gate array, an ASIC or the like, using verilog, for example with the function description provided herein. The image processing unit of the multiple image scanner comprises the image pre-processor 112, buffer 116 and image post-processor 120, which are described in more detail below.

A. Image Pre-Processor

Referring to FIG. 2, the image pre-processor 112 takes the RGB (red 106, green 108 and blue 110) image data from the CCD 104 and places either one or two different representations of that image into the buffer 114. One of the possible representations is a color image and the other is a monochrome image which is generated by selecting only one of the three color channels (red, green, or blue). The two different buffer images have the same y resolution but can have different x resolutions and bit depths. The bit depth of each image can be selected to be either 12-bit or 8-bit and the x resolution can be the CCD resolution divided by any integer factor from 1 to 63. The CCD resolution is the same for both images and can be either 300 ppi or 150 ppi. For example, the image pre-processor 112 can be programmed to put 300 ppi (x) by 300 ppi (y) 8-bit monochrome (green channel) data and 100 ppi (x) by 300 ppi (y) 12-bit color data into the buffer. Note that both images do not need to be generated. The pre-processor can be programmed to generate only the color representation or only the monochrome representation or both.

The four main functions performed by the image pre-processor of the present invention are described in greater detail below and with reference to FIGS. 1 and 2.

1. A/D Converter

The A/D convertor takes the 300 ppi or 150 ppi analog RGB image data from the CCD array and converts either 1 of the 3 or all 3 color values for each pixel to 10-bit digital numbers. These digital values are padded to 12 bits and sent to the dark clamp.

2. Dark Clamp

The dark clamp subtracts the average dark current for the line from each pixel value. Pixels inside the desired scan window are then sent to the compensator.

3. Compensator

The compensator removes pixel variations caused by non-uniform illumination and CCD response. Compensated pixel values are then sent to the prescaler.

4. Prescaler

The prescaler splits the compensated pixel values into a monochrome image and a color image, reduces the x-resolution of each image by a different integer factor, and puts one or both of the resulting images into the buffer. The prescaler splits the image data from the compensator into a monochrome stream and a color stream, reduces the x-resolution of each stream by a different integer factor, and then stores one or both of the resulting streams in the buffer. This is done to minimize the amount of buffer space consumed by each line of image data, especially when 2 views are requested by the host. For example, if no prescaler were provided and the host requested a 300 ppi monochrome view and a 100 ppi color view of an 8.5 inch wide scan window, each line of the image would consume 11.475 Kbytes of buffer space (8.5 inches 300 ppi 3 colors/pixel 1.5 bytes/color). However, with the prescaler each line consumes only 6.375 Kbytes (8.5 inches 300 ppi 1 color/pixel+8.5 inches 100 ppi 3 colors/pixel 1.5 bytes/color).

Note that the prescaler can either place full 12-bit or truncated 8-bit data into the buffer. The data width can be specified independently for each stream. The prescaler reduces the x-resolution of the 2 data streams by averaging adjacent pixels together rather than simply dropping pixels. This effectively lowpass filters the image data before it is resampled at the lower resolution and helps reduce aliasing. The prescaler can reduce x-resolution by any integer factor between 1 and 63.

B. Image Post-Processor

The image post-processor uses the image(s) in the buffer to generate either 1 or 2 views of the scan window specified by the host. Each view is generated from either the color image or the monochrome image. The two views can be generated from the same or different images. For example, one view could be generated from the color image and the other view from the monochrome image OR both views could be generated from the color image OR both views could be generated from the monochrome image. The two views can have different y resolution but the y resolution of each view must be the buffer y resolution divided by an integer factor from 1 to 16. The two views can also have different x resolutions which can be any resolution form 1/4 to 2X the x resolution of the buffer image from which the view is generated. Each view can also have different matrices, tonemaps, data types, etc. (with some restrictions which will be covered in greater detail below).

When two views are enabled, the views will be sent out interleaved on a line basis dependent on the ratio of their y resolutions. For example, if view one's y resolution is 300 and view two's y resolution is 150, then the data would alternate with two lines of view one's image data and then one line of view two's image data (except at the beginning). Other examples of interleaved data as a ratio of y resolution:

(2 to 1 ratio)→output 300 to 150 ratio: 300, 150, 300, 300, 150, 300, 300, 150 . . .

(1 to 2 ratio)→output 150 to 300 ratio: 150, 300, 300, 150, 300, 300, 150, 300 . . .

(3 to 1 ratio)→output 300 to 100 ratio: 300, 300, 100, 300, 300, 300, 100, 300, 300, 300 . . .

(1 to 3 ratio)→output 100 to 300 ratio: 300, 100, 300, 300, 300, 100, 300, 300, 300, 100 . . .

(4 to 1 ratio)→output 300 to 75 ratio: 300, 300, 75, 300, 300, 300, 300, 75, 300, 300 . . .

(1 to 4 ratio)→output 75 to 300 ratio: 300, 75, 300, 300, 300, 300, 75, 300, 300, 300 . . .

(5 to 1 ratio)→output 300 to 60 ratio: 300, 300, 300, 60, 300, 300, 300, 300, 300, 60 . . .

(1 to 5 ratio)→output 60 to 300 ratio: 300, 300, 60, 300, 300, 300, 300, 300, 60, 300 . . .

Note, the above examples are merely exemplary; other possible ratios for the current implementaion go up to 1 to 9.

The six main operations performed by the image post-processor of the present invention are described in greater detail below and with reference to FIGS. 1 and 3.

1. Line Merger

The line merger reads 1 to 9 lines from the appropriate image (color or black and white), optionally averaging some lines together before sending the resulting lines to the matrixer. The line merger essentially interleaves the two or more renditions of the scanned image into a single interleaved data stream to be sent to the host computer. By interleaving the two or more renditions of the scanned image on a line-by-line basis, the scanner does not have to save all of any rendition, as all renditions are generated, interleaved and sent to the host computer real time----that is, on a somewhat line-by-line basis.

The line merger reads 1 to 9 lines of data from either the color image or the black and white image and averages some of the lines together to reduce the number of computations that must be done by the matrixer. In addition, the line merger can provide a simple form of y resolution prescaling by averaging additional adjacent lines together. For example, the line merger can read 9 lines from the buffer, average every 3 adjacent lines to reduce the effective y resolution by a factor of 3, average the two remaining outer lines for kernel symmetry, and then send the resulting 2 lines to the matrixer. Therefore, it has reduced the number of lines 20 that must be processed by the matrixer from 9 to 2.

Any integer number of adjacent lines from 1 to N (where N is the number of lines read from the buffer--up to 9) can be averaged together. However, after adjacent lines have been averaged, the resulting number of lines must be 1, 3, 5, 7, or 9 so that symmetrical lines can be further averaged before being passed on to the matrixer. This means that if no adjacent lines are averaged, we can use either 1, 3, 5, 7, or 9 line kernels. However, if 2 or 3 adjacent lines are averaged, we can only use 1 or 3 line kernels. If 4 through 9 adjacent lines are averaged, we can only use a 1 line kernel.

Lines are averaged by adding the corresponding pixels of each line and dividing by a scale factor of 1, 2, 4, or 8. Therefore, exact averaging is obtained only when averaging together 1, 2, 4, or 8 lines. The line merger will overflow if the number of lines added together divided by the scale factor is greater than 2. Therefore, if 3, 5, 6, 7 or 9 line averaging is desired, the nearest lower scale factor should be used and the matrixer coefficients may need to be reduced to compensate for the extra "gain" introduced in the line merger. The only exception to this rule is when we are reading 9 lines from the buffer, averaging every adjacent 3 lines, and then using a 3 line kernel. In this case, the line merger will end up reducing 9 line to 2. One of these two lines (the one corresponding to the center of the kernel) will be obtained by adding the center 3 lines from the buffer. The other line will be obtained by adding the outer 6 lines from the buffer. However, only one divisor can be selected and must be selected such that no line coming out of the line merger has been multiplied by more than 2. Therefore, in this example, a divisor of 4 must be selected. Since the gain of the line merger is now 3/4, the matrixer coefficients may need to be increased to compensate.

The buffer image to be used (color or monochrome), the number of lines read from that image, the number of adjacent lines averaged, and the scale factor can be specified independently for each view to be generated.

2. Matrixer

The matrixer "mixes" the three colors of each pixel to produce a single color or three new colors before sending the lines on to the tone mapper.

3. Tone Mapper

The tonemapper uses lookup tables and interpolation to adjust image contrast and intensity before sending the data to the formatter. The output pixels are further transformed by the tonemapper which passes them through a lookup table which contains a transfer curve called the tonemap. Tonemaps are used to perform gamma correction, adjust contrast and intensity, enhance shadows, etc.

4. Formater

The formatter optionally thresholds or dithers the data before packing it into the specified data width. This stage can also invert the data, if desired, before sending it to the compression engine.

5. Compression Engine

The compression engine optionally uses the packbits algorithm to compress the line of image data before sending it to the host.

II. MULTIPLE VIEWS FROM ONE SCAN WINDOW

The multiple image scanner of the present invention has the ability to obtain two images from a single scan. The scanner command language (SCL) implementation of multiple image separates the concept of the scan window with the particular view of that window. SCL is the command language used for scanners and is commonly known. It should be noted that any command language could be used. However, in the preferred embodiment, SCL is used to generate multiple views from one scan window. The scan window is the physical area of the page that will be scanned (defined by the x and y position and the extents). The view of that scan window is the data contained inside the physical area (defined by the resolution, data type, mirror, inverse, etc.). There are scanner settings that are window and view independent (i.e., is ADF attached, serial number, etc.). The advantage of separating the view and the window is that it makes the definition of multiple views extensible to multiple window with multiple views. No other scanner has multiple image abilities or an implementation of multiple views. It should be noted that although in the present implementation of multiple views, a single scan is used to obtain multiple views of the same document, it is irrelevant whether one or more scans are used to obtain multiple views of the same document. It does not matter how the data is obtained (from one or more scans), the important point is that the SCL implementation of more than one view allows different data to represent the same space.

In a preferred embodiment, the Hewlett-Packard ScanJet 5p is utilized to allow the acquisition of two views of data simultaneously. However, it should be noted that any color scanner from any manufacturer could be modified to implement the present invention. While the region of the scan is the same, the data types and resolutions of the two views can vary. The limits on the variables set on the two views are described with the SetViewType macro in SCL as follows:

INT16 DualScan(INT16 Phase,

PUINT8 pBufferView0,

INT32 LengthView0,

PINT32 pReceivedView0,

PUINT8 pBufferView1,

INT32 LengthView 1,

PINT32 pReceivedView1);

The parameters are set as indicated below:

Phase----Flag indicating if this is the first transfer in a sequence. Must be one of the following values:

SL FIRST or SL SCAN, the first buffer in the transfer,

SL ADF SCAN, the first buffer in an ADF transfer (Currently only supported by HP1750A & HP5110A),

SL NEXT, each additional buffer transfer;

PbufferView0----Pointer to view 0 data buffer to receive the data;

LengthView0----Size of the view 0 data buffer in bytes;

pReceivedView0----Pointer to the actual number of bytes received from the scanner for view 0;

pBufferView1----Pointer to view 1 data buffer to receive the data;

LengthView1----Size of the view 1 buffer in bytes;

pReceivedView1----Pointer to the actual number of bytes received from the scanner for view 1.

This function is nearly identical to the Scano function, which is well known to those familiar with SCL, except that it supports the dual view mode of the scanner.

Some of the default settings for the two views of a scan are shown below in Table 1.

    ______________________________________     Parameter   Default: Image One                                 Default: Image Two     ______________________________________     Data Type   0 (b/w threshold)                                 5 (color)     Data width  1 bit/pixel     24 bits/pixel     B/W Dither Pattern                 0 (coarse fatting)                                 0 (coarse fatting)     Coefficient Matrix                 2 (green only)  0 (NTSC color)     Tone Map    0 (contrast/intensity)                                 0     Intensity   0               0     Contrast    0               0     Mirror      0 (off)         *     Auto Background                 0 (off)         *     Inverse Image                 0 (off)         0 (off)     X Resolution                 300 ppi         100 ppi     Y Resolution                 300 ppi         100 ppi     X Scale Factor                 100%            100%     Y Scale Factor                 100%            100%     X Location  0               *     Y Location  0               *     X Extent    2550 (pixels)   *     Y Extent    3300 (pixels)   *     Lamp        0 (off)         *     Scan Bar Position                 stops where it is                                 *     Download Type                 0 (b/w dither pattern)                                 0 (b/w dither                                 pattern)     Downloaded 8×8 B/W                 none (old pattern is erased)                                 *     Dither Pattern     Downloaded 8 bit                 none (old map is erased)                                 *     Tone Map     Downloaded Color                 none (old matrix is erased)                                 *     Matrix     Downloaded  none (old parameters                                 *     Calibration erased)     Strip Parameter     Downloaded 16×16                 none (old pattern is erased)                                 *     B/W Dither Pattern     Downloaded B/W                 none (old matrix is erased)                                 *     Matrix     Downloaded 10 bit                 none (old parameters                                 *     Color Matrix                 erased)     Downloaded RGB                 none (old parameters                                 *     tone maps   erased)     Downloaded B/W                 none (old parameters                                 *     tone maps   erased)     Downloaded RGB                 none (old parameters                                 *     gains       erased)     Calibration Y-Start                 -1 (white strip)                                 *     Calibration Strip                 0 (auto-select) *     parameters     Calibration Mode                 0 (auto--calibration                                 *                 dependent on data width)     Speed Mode  0 (auto)        *     Compression 0 (off)         0 (off)     Select number views                 1               NA     Selected view                 1 (off)         NA     Calibration Strip                 0 (calculated)  *     Lower     Max. # Lines per                 0 (use calculated)                                 *     Buffer     ______________________________________

In the above table "*" indicates that the parameter is not set independently for the two views. However, this could be modified to allow some or all of these parameters to be independently set for the two views. Also, these parameter settings and SCL commands reflect the implementation used by the inventors and is not intended to be the only possible combination of parameter settings or SCL commands that could enable the multiple views from a single scan concept of the present invention.

The following commands have been added to select the number of views to be sent by the scanner to the host computer:

Command: Select Number of Views

Escape Sequence: Esc*f#A

Inquire ID: 10466

Range: 1-2

Default: 1

Macro: SetNumberofViews(x)

Send Command: SendCommand(SL NUM OF VIEWS,x)

Where x can be either 1 or 2.

This command will select how many views of the window will be sent by the scanner. The default will be one. The present implementation supported values are 1=one view, 2=two views. When two views are enabled, the data for the two views will be sent out interleaved on a line basis dependent on the ration of their Y resolutions. For example, if view one's Y resolution was 300 and view two's Y resolution was 150, then the data would alternate with two lines of view one's image and then one line of view two's image (except at the start; see examples above in the image post-processor section).

The select view command is used to set scanner settings for the view or views you want to work with as follows:

Command: Select view

Escape Sequence: Esc*f#B

Inquire ID: 10467

Range: 0-1

Default: 0

Macro: SetViewType(x)

SendCommand: SendCommand(SL VIEW TYPE, x)

Where x can be: 0--for view one, or 1--for view two.

The view must be selected prior to choosing the scanner settings. This command selects which view the subsequent SCL commands or inquires refer to. Supported values are: 0(view one) and 1(view two). The default is view one.

III. METHOD FOR PARSING MULTIPLE IMAGE SCAN DATA

Host computer software parses the interleaved multiple image data sent by the scanner. In the present implementation, the software program DualScan and its supporting modules permit a user unfamiliar with the details of the multiple image data format to easily parse multiple image data from the scanner into familiar tiff files, which can then be used with programs such as Photo Shop. DualScan is a software program sold by Hewlett-Packard Co. It is possible that one or both of the images will contain compressed data further complicating the parsing issue. The DualScan software allows use of a scanner with multiple image capability in its hardware by parsing the interleaved data stream received from the scanner. One skilled in the art could readily expand DualScan to include the parsing of multiple views of data, rather than the two views as described in the present implementation.

FIG. 4 is a block diagram of a dual image data stream 136 being sent from the scanner (not shown) and parsed by a data stream parser 122 on the host computer (not shown) into view 1 data (monochrome image) 126 and view 2 data (color image) 124. The operation of the data stream parser will be further explained with reference to FIG. 5, which is a flow chart of the data stream parsing function.

At the initial entry point, the resolution, compression state, and bytes per line for each of the images is inquired by the data parser at 200. Next image ratios for each view are calculated by the data parser at 202. Then interleaved image data is received by the data parser from the scanner at 204. The data parser then copies one line of scan data to the appropriate output buffer, decompressing the data if necessary at 206. The data parser then switches views (210) based on the image ratios calculated at 202. If no errors are detected and the parsing of the data stream is not finished (212), the data parser returns to 204 and receives 5 more interleaved data from the scanner to be parsed. If an error is detected or the parsing of the data stream is completed at 212, the data parser returns this status to the calling function which takes an appropriate action. Error conditions may include: (1) output buffers full, (2) bad response from the scanner, (3) decompression engine out of data and scanner has no more data, or (4) scan completed. The steps in FIG. 5 are also shown in source code in Appendix

It should be noted that although the implementation described herein describes a dual scan, dual views, and the parsing of two interleaved data streams, these concepts are readily extensible to multiple scan, multiple views, and the parsing of multiple interleaved data streams.

The foregoing description of the present invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and other modifications and variations may be possible in light of the above teachings. For example, the data stream parser is capable of parsing any interleaved data stream containing more than one set of data. The data stream does not have to be an scanned image data stream. Also, the SCL implementation of multiple views of the same window does not matter how the multiple views were obtained; the implementation is the same whether the views were obtained from one or more scans of the same area. The embodiment was chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilize the invention in various embodiments and various modifications as are suited to the particular use contemplated. It is intended that the appended claims be construed to include other alternative embodiments of the invention except insofar as limited by the prior art. 

What is claimed is:
 1. A method for parsing an interleaved multiple data stream into the individual data streams contained in the interleaved multiple data stream, said method comprising the following steps:(a) determining the data type and other parameters of each of the individual data streams contained in the interleaved multiple data stream; (b) calculating the data ratios for each individual data stream contained in the interleaved multiple data stream; (c) receiving the interleaved multiple data stream, any individual data stream contained in said interleaved multiple data stream may be compressed; (d) copying each line of the individual data streams into predetermined buffers; (e) performing decompression on any individual data stream as necessary; (f) switching between the individual data streams based on the data ratios calculated in step (b) above; and (g) returing to step (c) until the interleaved multiple data stream is completed.
 2. A method for parsing an interleaved multiple image data stream into each individual view contained in the interleaved multiple image data stream, said method comprising the following steps:(a) determining the data type and other parameters of each individual view contained in the interleaved multiple image data stream; (b) calculating the image ratios for each individual view contained in the interleaved multiple image data stream; (c) receiving the interleaved multiple image data stream, any individual view contained in said interleaved multiple image data stream may be compressed; (d) copying each line of the individual views contained in the interleaved multiple image data stream into predetermined buffers; (e) performing decompression on any individual view as necessary; (f) switching between the individual views contained in the interleaved multiple image data stream based on the image ratios for each view calculated in step (b) above; and (g) retuning to step (c) until the interleaved multiple image data stream is completed. 